System, method and computer-readable medium for encoding a signal into macroblocks

ABSTRACT

A quantizer and dequantizer for use in a video coding system that applies non linear, piece-wise linear scaling functions to video information signals based on a value of a variable quantization parameter. The quantizer and dequantizer apply different non linear, piece-wise linear scaling functions to a DC luminance signal, a DC chrominance signal and an AC chrominance signal. A code for reporting updates of the value of the quantization parameter is interpreted to require larger changes when the quantization parameter initially is large and smaller changes when the quantization parameter initially is small.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 13/868,042,filed Apr.l 22, 2013, now U.S. Pat. No. 9,392,271, which is a continuation of U.S. patent application Ser. No. 13/307,388, filed Nov. 30, 2011, now U.S. Pat. No. 8,665,965, which is a continuation of U.S. patent application Ser. No. 12/776,106, filed May 7, 2010, now U.S. Pat. No. 8,279,940, which is a continuation of U.S. patent application Ser. No. 11/170,622, filed Jun. 29, 2005,now U.S. Pat. No. 7,738,555, which is a continuation of U.S. patent application Ser. No. 10/664,985, filed Sep. 18, 2003, now U.S. Pat. No. 7,269,219, which is a continuation of U.S. patent application Ser. No. 09/974,788, filed Oct. 12, 2001, now U.S. Pat. No. 6,654,418, which is a continuation of U.S. patent application Ser. No. 08/899,096, filed Jul. 24, 1997, now U.S. Pat. No. 6,347,116, which claims priority to U.S. Provisional Application No. 60/038,016, filed Feb. 14, 1997; and all of which are herein incorporated by reference in their entirety.

BACKGROUND OF THE INVENTION

The present invention related to a quantizer for use in image coding. It is known to scale discrete cosine transformation coefficients in video coding applications to conserve bandwidth. Known systems either scale by a small constant, such as divide by 8, or scale by a linear scaling factor that is twice a quantization parameter (2×Q_(p)). Scaling by the small constant does not achieve significant bandwidth savings. Scaling by the 2*Q_(p) linear scaling function achieves significant bit savings, but results in poor image quality at lower and mid-level Q_(p) values particularly in the chrominance video signals. Accordingly, there is a need in the art for a quantizer characterized by a scaling function that achieves good signal quality, and achieves bit rate savings for all values of Q_(p) particularly for chrominance.

An encoder and decoder must use the same quantization parameter to encode and decode video information intelligibly. Known systems report changes to the quantization parameter with codes that cause changes in Q_(p) with a uniform step size, regardless of the value of Q_(p).

Experience teaches that, at low values of Q_(p), changes in Q_(p) are relatively small. However, for large values of Q_(p), changes in Q_(p) values are relatively large. Systems that allocate additional bits to report the larger Q_(p) changes waste bandwidth at the lower Q_(p) values where the large changes do not occur. However, systems that limit the number of bits available to coding Q_(p) changes may become saturated if larger charges must be coded. Accordingly, there is a need in the art for a quantizer that reports both large and small changes is Q_(p) with a minimum number of bits.

The disadvantages of the art are alleviated to a great extent by a quantizer that applies a non-linear scaling function based on the quantization parameter. A different scaling function applies for luminance data than chrominance data. Both scaling functions at low Q_(p) values approximate constant scaling functions. At large Q_(p) values, the luminance scaling function approximates a Z*Q_(p) scaling function and the chrominance scaling function approximates a 1*Q_(p) scaling function. The quantizer may include a non-linear scaling function for AC coefficients.

The present invention may include a way to update values of Q_(p). Changes in Q_(p) are reported in a fixed length code, but each code means different things based on the previous values of Q_(p). If the previous Q_(p) value is large, the code represents a larger change than if the previous value of Q_(p) were small.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1(a) is a block diagram of a first embodiment of an encoder 100 of the present invention; FIG. 1(b) is a block diagram of a first embodiment of a decoder 200 of the present invention.

FIG. 2 is a block diagram of a portion of the quantizer of FIG. 1.

FIG. 3 is a block diagram of a portion of the scaling circuit of FIG. 1.

DETAILED DESCRIPTION

FIG. 1 shows an encoder 100 constructed in accordance wish a first embodiment of the present invention. An analog image signal is presented to the encoder 100. The image signal is sampled and converted to a digital signal by an analog to digital (“A/D”) converter 110 using techniques known in the art. The A/D converter 110 generates a digital image signal for a plurality of pixels of the image. Alternatively, the image signal may be presented to the encoder 100 as a digital image signal; in this case, the A/D converter 110 is omitted.

The digital image signal is input to a processing circuit 120. The processing circuit 120 may perform a host of functions. Typically, the processing circuit 120 filters the image data and breaks the image data into a luminance signal component and two chrominance signal components. Additionally, the processing circuit 120 groups image data into blocks of data. Where the digital input signal represents information for a plurality of pixels in a scanning direction, the digital output of the processing circuit 120 represents a block of pixels, for example an 8 pixel by 8 pixel array of image data. The processing circuit 120 outputs image data on a macro block basis. A macro block typically consists of up to four blocks of luminance data and up to two blocks of chrominance data. The processing circuit 120 may also perform additional functions, such as filtering, to suit individual design criteria.

The output of the processing circuit 120 is input to a transform circuit 130. The transform circuit 130 performs a transformation of the image data, such as discrete cosine transform (“DCT”) coding, from the pixel domain to a domain of coefficients. A block of 64 pixels is transformed to a block of 64 coefficients. Coefficients output by DCT coding include a single DC coefficient and 63 AC coefficients, few of which are non-zero. The transform circuit 130 outputs blocks of coefficients organized into macro blocks.

A quantizer 140 scales the DC and AC coefficients generated by the prediction circuit 150 according to a non-linear scaling function governed by a variable quantization parameter (Q_(p)). The quantization parameter is a value determined by the bit rate of the channel, the resolution of the image being coded, the type of image coding (intra or inter) and other factors that affect a number of bits that may be allocated to coding of the macro block. Q_(p) is updated on a macro block by macro block basis; changes in Q_(p) are reported in an output bitstream. In MPEG coding, Q_(p) takes on values between 1 and 31. The quantizer 140 reduces bandwidth of the image signal by reducing a number of quantization levels available to encoding the signals. Many small coefficients input to the quantizer 140 are divided down and truncated to zero. The scaled signals are output from the quantizer 140.

The output of the quantizer 140 is input to a prediction circuit 150. The prediction circuit 150 performs gradient prediction analysis to predict the DC coefficient of the block. The prediction circuit 150 may pass the AC coefficients generated by the transform circuit 130 or, alternatively, may predict AC coefficients of the block. In a preferred mode of operation, the prediction circuit 150 selects between modes of predicting or passing AC coefficients; in this case, the prediction circuit 150 generates an AC prediction flag to identity a mode of operation. The prediction circuit 150 outputs DC coefficient signals and AC coefficient signals (representing either AC coefficients or AC residuals) on a macro block basis and, on a macro block basis optionally, an AC prediction flag.

A variable length coder 150 encodes the output of the quantizer 140. The variable length coder 160 typically is a Huffman encoder that performs run length coding on the scaled signals. A bitstream output from the variable length coder 160 may be transmitted, stored, or put to other uses as are known in the art.

A decoder 200 performs operations that undo the encoding operation described above. A variable length decoder 260 analyzes the bit stream using a complementary process to recover a scaled signal. If a Huffman encoder were used by the encoder 160, a Huffman decoder 260 is used.

A reconstruction circuit 250 performs the identical gradient analysis performed in the prediction circuit 150. The DC residual signal is identified and added to a predicted coefficient to obtain a DC coefficient. Optionally, the reconstruction circuit 250 may identify the AC prediction flag and, based on the status of that flag, interprets the AC information as either AC coefficient information or AC residual information. In the event that AC residual information is present, the reconstruction circuit 250 adds the residual signals to corresponding predicted signals to obtain AC coefficients. The reconstruction circuit 250 outputs coefficient signals.

A dequantization circuit 240 multiplies the recovered signals by the same scalar values used at the quantizer 140. Of course, those coefficients divided down to zero are not recovered.

An inverse transformation circuit 230 performs the inverse transformation applied by the transform circuit 130 of encoder 100. If DCT transformation were performed, an inverse DCT transformation is applied. So, too, with sub-band coding. The inverse transformation circuit 230 transforms the coefficient information back to the pixel domain.

A processing circuit 220 combines luminance and chrominance signals and may perform such optional features as are desired in particular application. The processing circuit 220 outputs digital signals of pixels ready to be displayed. At this point the signals are fit for display on a digital monitor. If necessary to fit a particular application, the signals may be converted by a digital to analog converter 210 for display on an analog display.

The present invention achieves bit rate savings by applying a non-linear scaler function at the quantizer 140 to obtain bit rate savings at high Q_(p) levels but ensure high video quality at low Q_(p) levels. The quantizer 140 applies different scalar functions depending upon the type of data being quantized (luminance or chrominance), the type of coefficient being quantized (DC or AC) and the type of coding (inter or intra) being performed.

Non-Linear Quantization of DC Coefficients for Luminance and Chrominance

For DC coefficient information, the scaler functions vary with Q_(p). Different piece-wise linear scaler functions are applied to DC luminance and DC chrominance signals. To minimize objectionable artifacts within the chrominance signal, the DC chrominance scaler is smaller than the DC luminance scaler for all Q_(p) values.

The DC luminance scaler function for low Q_(p) values is a constant. For large Q_(p) levels, the DC luminance scaler function approximates a 2*Q_(p) function. The inventors obtained through experimentation the DC scaler function shown in Table 1 below, used in an embodiment of the invention.

The DC chrominance scaler function is also at a constant at low values Q_(p). At high Q_(p) values, the DC chrominance scaler function approximates a linear scaler function in Q_(p). The inventors obtained through experimentation the DC scaler function for chrominance signals shown in Table 1 below, used in a preferred embodiment.

TABLE 1 DC Scaler for Quantizer (Q_(p)) Range Component 1 through 4 5 through 8 9 through 24 25 through 31 Luminance 8 2 * Q_(p) Q_(p) + 8 2 * Q_(p) − 16 Chrominance 8 (Q_(p) + 13)/2 (Q_(p) + 13)/2 Q_(p) − 6

Rather than compute the DC scaler for each value of Q_(p), further efficiencies may be obtained by storing the DC scaler functions for luminance and chrominance for all values of Q_(p) in a memory table at the quantizer 140. In this event, the quantizer 140 includes a small memory of DC scales for luminance and chrominance that may be indexed by Q_(p) as shown in Table 2 below.

TABLE 2 Q_(p) DC Scaler for Luminance DC Scaler for Chrominance 1 8 8 2 8 8 3 8 8 4 8 8 5 10 9 6 12 9 7 14 10 8 16 10 9 17 11 10 18 11 11 19 12 12 20 12 13 21 13 14 22 13 15 23 14 16 24 14 17 25 15 18 26 15 19 27 16 20 28 16 21 29 17 22 30 17 23 31 18 24 32 18 25 34 19 26 36 20 27 38 21 28 40 22 29 42 23 30 44 24 31 46 25

In operation, the transform circuit 130 outputs macro blocks of data to the quantizer 140. Each macro block contains as many as four blocks of luminance data and two blocks of chrominance data. A single Q_(p) value is used for the macro block. Q_(p) is updated on a macro block by macro block basis.

Based on the value of Q_(p), the quantizer 140 recalls a DC scaling factor for luminance and a DC scaling factor for chrominance determined by the scaling functions at the value of Q_(p). For each luminance block, the quantizer 140 generates a DC lum level signal according to:

DC lum level=DC lum coefficient/DC Scaler for Luminance.

For each chrominance block, the quantizer 140 generates a DC chrom level signal according to:

Chrom DC level=Chrom DC coefficient/DC Scaler for Chrominance.

The quantizer 140 outputs each DC lum level signal and each DC chrom level signal.

The non-linear DC scaling functions of the quantizer 140 may be implemented in hardware as shown in FIG. 2. The Q_(p) signal is input to a memory 300 that stores the scaler factors defined by the DC luminance and DC chrominance scaler functions. The scaler table 300 may be substituted by a processor (not shown) that computes the scaler factors according to the Q_(p) value. DC luminance and DC chrominance signals from the transform circuit 130 are isolated by a demultiplexer 310 and routed to respective luminance and chrominance division circuits 320 and 330. The DC lum level and DC chrom level signals are generated by these division circuits.

At the decoder 200, the dequantization circuit 240 performs an inverse quantization operation with the same piece-wise linear scaling functions. Based on the Q_(p) value of the immediately preceding macro block and any Q_(p) update reported in the incoming bitstream, the dequantization circuit 240 recalls appropriate scaling factors for DC luminance and DC chrominance signals. For each luminance block, the dequantization circuit 240 generates a luminance DC coefficient according to:

Lum DC coefficient=DC Lum Level*DC Scaler for Luminance.

For each chrominance block, the scaling circuit 240 generates a DC coefficient according to:

Chrom DC coefficient=Chrom DC Level*DC Scaler for Chrominance.

The dequantization circuit 240 outputs the reconstructed luminance and chrominance coefficients.

The non-linear DC scaling functions of the dequantization circuit 240 may be implemented in hardware as shown in FIG. 3. The Q_(p) signal is input to a memory 400 that stores the scaler factors defined by the DC luminance and DC chrominance scalar functions. The scaler table 400 may be substituted by a processor (not shown) that computes the scalar factors according to the Q_(p) signal. DC lum level and DC chrom level signals from the variable length encoder 260 are isolated by a demultiplexer 410 and routed to respective luminance and chrominance multiplication circuits 420 and 430. DC luminance coefficients and DC chrominance coefficients are generated by these multiplication circuits.

The non-linear DC scaling factors described above are appropriate to both intra and inter coding operations. However, experience teaches that DC coefficients obtained from inter coding often are near zero. When quantized even by a constant scaling factor, the DC coefficients obtained from inter coding often are truncated to zero. Accordingly, to reduce complexity in a preferred embodiment, the non-linear scaling function may be disabled during inter coding operations. The DC coefficients obtained from inter coding may be quantized in a manner similar to the quantization of AC coefficients, discussed below.

The non-linear DC scaling functions maintain high coding quality at low Q_(p) values and achieve significant bit rate savings at high Q_(p) values. The quantizer 140 and dequantization circuit 240 of the present invention may find use in applications where image quality is a more significant consideration than bit rate savings. Accordingly, in a preferred embodiment, the quantizer 140 and scaler circuit 240 may have two modes of operation: A first mode applying non-linear scaling functions based on values of Q_(p) as described above, and a second mode applying a constant scaling factor (such as divide by 8) or even one of a plurality of constant scaling factors (such as divide by 8, 4, 2 or 1). In this embodiment, the quantizer 140 generates a scaler flag signal identifying which mode of operation is being used. The dequantization circuit 240, upon receipt of the scaler flag signal, invokes an appropriate mode of operation to generate coefficients. The scaler flag signal may be a one bit signal when discriminating among the two modes, but may be larger when discriminating among the two modes and additionally identifying which of constant scaling factors is invoked.

Non-Linear Quantization of Chrominance Coefficients for Inter Coded Blocks

In inter coding, both DC and AC coefficients of chrominance blocks may be close to zero. Coding of such coefficients with non-linear scaling functions may improve coding quality of the chrominance signal. Additionally, the non-linear scaling functions of this section may be applied to AC coefficients of chrominance blocks in intra coding to achieve coding efficiencies.

The non-linear scaling function for AC chrominance coefficients is piece-wise linear and based on Q_(p) values. At low values for Q_(p), the non-linear scaling function for AC is a constant value, almost half of the level of the scaling function for DC chrominance signals. At high levels for Q_(p), the AC scaling function approximates a Q_(p)/2 line. At intermediate levels, the AC scaling function approximates a Q_(p)/4 line. In one preferred embodiment, the AC scaling function for chrominance was derived experimentally as shown in Table 3 below:

TABLE 3 Quantizer for Chrominance when Q_(p) in Range Component 1 through 4 5 through 8 9 through 24 25 through 31 Chrominance 4 (Q_(p) + 13)/4 (Q_(p) + 13)/4 (Q_(p) − 6)/2 The AC scaling factors for chrominance also may be stored in the quantizer 140 in a memory table indexed by Q_(p).

During coding, the quantizer 140 recalls or computes a scaling factor for AC coefficients based on the value of Q_(p). For each chrominance AC coefficient, the quantizer 140 generates a corresponding chrominance AC level signal according to:

Chrom AC level=Chrom AC coefficient/Quantizer for Chrominance.

The quantizer 140 outputs the Chrom AC level signals for the AC coefficients.

The non-linear scaling functions for AC chrominance coefficients may be implemented in hardware, also shown in FIG. 2. The scaler table 300 stores the AC chrominance scaler values indexed by Q_(p). If scaler table 300 is substituted by a processor, the processor computes the AC chrominance scaler values according to the Q_(p) value. AC chrominance signals from the transform circuit 140 are isolated by a demultiplexer 310 and routed to an AC division circuit 340. The AC chrom level signals are generated by the division circuit 340.

During decoding, the dequantization circuit 240 recalls the AC scaling factor for chrominance based on the value of Q_(p) used for the immediately previous macro block and any Q_(p) update provided in the incoming bitstream. For each AC chrominance level signal, the scaling circuit 240 reconstructs a corresponding AC chrominance coefficient according to:

Chrom AC coefficient=Chrom AC Level*Quantizer for Chrominance.

The scaling circuit 240 outputs the reconstructed chrominance AC coefficients.

The scaling circuit's non-linear AC scaling functions may be implemented in hardware, also shown in FIG. 3. The scaler table 400 stores the AC chrominance scaler values indexed by Q_(p). If scaler table 400 is substituted by a processor, the processor computes the AC scaler value according to the Q_(p) signal. AC chrom level signals from the variable length encoder 160 are isolated by a demultiplexer 410 and routed to an AC multiplication circuit 440. The AC coefficients are generated by the multiplication circuit 440.

Quantizer Update

The encoder 100 and decoder 200 each must use the same Q_(p) value for video signals to be encoded and decoded intelligibly. The encoder 100 may change a value of Q_(p) as frequently as every macro block. When the encoder 100 changes Q_(p), it reports the change in a Q_(p) update signal in the output bitstream.

The present invention provides for an improved method of reporting updated Q_(p) values to the decoder 200. For each Q_(p) update, the magnitude of the Q_(p) adjustment depends not only on the update signal but also the previous value of Q_(p). A given Q_(p) update signal at a large value of Q_(p) results in a relatively large change in Q_(p). The same Q_(p) update signal at a small value of Q_(p) results in a smaller change in Q_(p). The following Table 4 demonstrates Q_(p) adjustments made based on the Q_(p) update signal and the value of Q_(p) in one preferred embodiment of the invention.

TABLE 4 DQuant Qp Change Based on Qp Value Code 1 through 8 7 through 13 14 through 21 22 through 31 00 −1 −1 −2 −3 01 −2 −3 −4 −5 10 1 1 2 3 11 2 3 4 5

Providing variable step sizes for Q_(p) updates based on the value of Q_(p) provides resistance to saturation for large changes of Q_(p) at the encoder 100. The variable step sizes provide increased flexibility without requiring additional overhead because the previous value of Q_(p) is known at the decoder 200 and need not be reported in the bitstream. 

What is claimed is:
 1. An encoder comprising: a processor; and a computer-readable storage medium storing instructions which, when executed by the processor, cause the processor to perform operations, the operations comprising: receiving a block of data; determining an update code representing a first adjustment to a quantization parameter for the block of data as follows: (i) determining a first 2-bit code to be the update code, when the first adjustment equals −1; (ii) determining a second 2-bit code to be the update code, when the first adjustment equals −2; (iii) determining a third 2-bit code to be the update code, when the first adjustment equals 1; or (iv) determining a fourth 2-bit code to be the update code, when the first adjustment equals 2; and sending the update code to a decoder.
 2. The encoder of claim 1, wherein the update code is for the decoder to update a value of a previous quantization parameter using the first adjustment.
 3. The encoder of claim 1, wherein the first 2-bit code, the second 2-bit code, the third 2-bit code and the fourth 2-bit code are in a binary format.
 4. The encoder of claim 3, wherein the first 2-bit code is a binary value of 00, wherein the second 2-bit code is a binary value of 01, wherein the third 2-bit code is a binary value of 10, and wherein the fourth 2-bit code is a binary value of
 11. 5. The encoder of claim 3, wherein the first adjustment is applicable whenever a previous quantization parameter falls within a first range of values.
 6. The encoder of claim 5, wherein the first range of values comprises values 1through 6, inclusive.
 7. The encoder of claim 5, wherein a second adjustment is determined in lieu of the first adjustment whenever the previous quantization parameter falls within a second range of values as follows: (v) for the first 2-bit code, the second adjustment equals −1; (vi) for the second 2-bit code, the second adjustment equals −3; (vii) for the third 2-bit code, the second adjustment equals 1; and (viii) for the fourth 2-bit code, the second adjustment equals
 3. 8. The encoder of claim 7, wherein the second range of values comprises values 7through 13, inclusive.
 9. The encoder of claim 7, wherein a third adjustment is determined in lieu of the first adjustment and the second adjustment whenever the previous quantization parameter falls within a third range of values as follows: (ix) for the first 2-bit code, the third adjustment equals −2; (x) for the second 2-bit code, the third adjustment equals −4; (xi) for the third 2-bit code, the third adjustment equals 2; and (xii) for the fourth 2-bit code, the third adjustment equals
 4. 10. The encoder of claim 9, wherein the third range of values comprises values 14through 21, inclusive.
 11. The encoder of claim 9, wherein a fourth adjustment is determined in lieu of the first adjustment, the second adjustment, and the third adjustment whenever the previous quantization parameter falls within a fourth range of values as follows: (xiii) for the first 2-bit code, the fourth adjustment equals −3; (xiv) for the second 2-bit code, the fourth adjustment equals −5; (xv) for the third 2-bit code, the fourth adjustment equals 3; and (xvi) for the fourth 2-bit code, the fourth adjustment equals
 5. 12. The encoder of claim 11, wherein the fourth range of values comprises values 22 through 31, inclusive.
 13. A method comprising: receiving, by a processor, a block of data; determining, by the processor, an update code representing a first adjustment to a quantization parameter for the block of data as follows: (i) determining a first 2-bit code to be the update code, when the first adjustment equals −1; (ii) determining a second 2-bit code to be the update code, when the first adjustment equals −2; (iii) determining a third 2-bit code to be the update code, when the first adjustment equals 1; or (iv) determining a fourth 2-bit code to be the update code, when the first adjustment equals 2; and sending, by the processor, the update code to a decoder.
 14. The method of claim 13, wherein the update code is for the decoder to update a value of a previous quantization parameter using the first adjustment.
 15. The method of claim 13, wherein the first 2-bit code, the second 2-bit code, the third 2-bit code and the fourth 2-bit code are in a binary format.
 16. The method of claim 15, wherein the first 2-bit code is a binary value of 00, wherein the second 2-bit code is a binary value of 01, wherein the third 2-bit code is a binary value of 10, and wherein the fourth 2-bit code is a binary value of
 11. 17. The method of claim 15, wherein the first adjustment is applicable whenever a previous quantization parameter falls within a first range of values.
 18. The method of claim 17, wherein the first range of values comprises values 1through 6, inclusive.
 19. The method of claim 17, wherein a second adjustment is determined in lieu of the first adjustment whenever the previous quantization parameter falls within a second range of values as follows: (v) for the first 2-bit code, the second adjustment equals −1; (vi) for the second 2-bit code, the second adjustment equals −3; (vii) for the third 2-bit code, the second adjustment equals 1; and (viii) for the fourth 2-bit code, the second adjustment equals
 3. 20. The method of claim 19, wherein a third adjustment is determined in lieu of the first adjustment and the second adjustment whenever the previous quantization parameter falls within a third range of values as follows: (ix) for the first 2-bit code, the third adjustment equals −2; (x) for the second 2-bit code, the third adjustment equals −4; (xi) for the third 2-bit code, the third adjustment equals 2; and (xii) for the fourth 2-bit code, the third adjustment equals
 4. 